Download ppt - QEC14

What’s QEC to Solid State Physics
David DiVincenzo
17.12.2014
QEC14
Outline
• Surface codes everywhere (and even color
codes)
• Various rough approximations of scalability
• Attempting to get error & leakage rates under
control – example from quantum dot qubits
• The highly complex classical world of surface
codes – example from UCSB/Google
• Outside the gate model – one-shot syndrome
measurement
• Inside the gate model – Fibonnaci anyons
A development of 1996-7:
X
X
In Quantum Communication, Computing, and Measurement, O. Hirota et al., Eds. (Plenum, New York, 1997).
Stabilizer generators XXXX, ZZZZ;
Stars and plaquettes of interesting
2D lattice Hamiltonian model
X
X
Z
Z
Z
Z
A development of 1996-7:
X
X
In Quantum Communication, Computing, and Measurement, O. Hirota et al., Eds. (Plenum, New York, 1997).
Stabilizer generators XXXX, ZZZZ;
Stars and plaquettes of interesting
2D lattice Hamiltonian model
X
X
Z
Z
Z
Z
Colorized thanks to
Jay Gambetta and John Smolin
Surface code
Q
Q
Q
Q
Q
Q
Q
Q
|0Q
Q
|0Q
Q
|0Q
Q
Q
Q
Q
Q
Q
Q
Q
Q
|0Q
Q
|0Q
Q
|0Q
Q
Initialize Z syndrome
qubits to
One level of abstraction – CNOTs on
square lattice with data qubits (blue)
and ancilla qubits (red and green)
Slightly less abstract – geometric layout of qubits & couplers to
implement desired square lattice
Blue: data
Red/green: ancilla
Numbering:
qubits with
distinct transition
frequencies
“Realistic” chip layout of qubits and resonators
• Qubits (green) coupled via
high-Q superconducting
resonators (gray)
• “skew-square” layout of
qubits and resonators is one
way to achieve abstract
square
• Every qubit has a number of
controller and sensor lines to
be connected to the outside
world (gold pads)
DP. DiVincenzo, “Fault tolerant
architectures for superconducting
qubits,” Phys. Scr. T 137 (2009) 014020.
Another “Realistic” surface code layout in 3D
circuit-QED architecture
Syndrome measurements without the
execution of a quantum circuit
DiVincenzo & Solgun, New J. Phys. 2013
Another “Realistic” surface code layout for doublequantum-dot qubit
Mehl, Bluhm, DiVincenzo
“Fault-Tolerant Quantum
Computation for SingletTriplet Qubits with
Leakage Errors,” in
preparation
arXiv:1411.7403
Not obvious that this is a scalable implementation
Progress error correction in ion traps,
But another not-really-scalable setup
Fig. S4
Steane 7-qubit error correction
code as first step to “color code
carpet”
Uni. Innsbruck
Two-electron spin qubits
Electrostatic gates
GaAs heterostructure
90 nm
+
+ + + + + + + + + + + +
2D electron gas
Individual confined electrons
Thanks to Hendrik Bluhm, RWTH
Qubit manipulation
E
S(0, 2)
Qubit states
J()
0
 << 0: Free precession
Bext+Bnuc,z
S 


T0


1
  
2
1

  
2


DBz
 ~< 0: Coherent exchange
T0
J

S
potential energy
There are many kinds of noise
(e.g., charge noise)
Representative gate
• 10 to 32 pulse
segments
• Reminiscent of Rabi,
but more fine
structure.
1 - F ≈ 0.2 % typical
=> Good gates exist, but can these complicated pulses
actually be tuned?
First experimental steps – Pascal Cerfontaine
and Hendrik Bluhm
Experimental trajectory reconstructed via self-consistent state
tomography (Takahashi et al, PRA 2013).
Entangling operation of STQs
singly occupied: exchange
18.-21.08.2014 | DiVincenzo
Mehl & DiVincenzo, PRB 90, 045404
(2014)
19
Essential: Leakage Reduction Units
Similar (but not worse than) entangling gates
Mehl, Bluhm, DiVincenzo, in preparation
Vision: Scalable architecture
Needed: quantum information theorists
21
Case study:
Back to UCSB/Google
Classical control: 23 control wires for the 9 qubits!
Waveforms of classical signals going to the dilution refrigerator
10 kW power consumption
Final observation on UCSB/Google:
-- Their instinct (also DiCarlo, TU Delft) is to report error rates of full
Cycles; focus is not on individual gate errors
An architecture to do surface code operations without
using the circuit model
4 “transmon” qubits antenna coupled to
cubical electromagnetic cavity
DiVincenzo & Solgun, New J. Phys. 2013
Phase shift of signal reflected from cavity vs. frequency
0000 qubit state
0001
0011
1111
θ is the same for all even states (mod 2π)
θ is the same for all odd states (mod 2π)
0111
θeven≠θodd
“Fibonacci” Levin-Wen Model
Levin & Wen, PRB 2005
v
p
H    Qv   Bp
v
Vertex
Operator
Qv = 0,1
p
Plaquette
Operator
Bp = 0,1
Trivalent Lattice
Ground State
Qv = 1 on each vertex
Bp = 1 on each plaquette
“Fibonacci” Levin-Wen Model
Levin & Wen, PRB 2005
v
p
H    Qv   Bp
v
Vertex
Operator
Qv = 0,1
p
Plaquette
Operator
Bp = 0,1
Trivalent Lattice
Ground State
Qv = 1 on each vertex
Bp = 1 on each plaquette
Excited States are Fibonacci
Anyons
H    Qv   Bp
Vertex Operator: Qv
j
Qv
i
v
k
  ijk
v
j
i
v
k
p
“Fibonacci” Levin-Wen Model
100   010   001  0
All other  ijk  1
H    Qv   Bp
Plaquette Operator: Bp
v
p
Bp  1
on each plaquette
superposition of loop
states
b
b
a
s
p
B
i
n
f
j
p
m
a
c
k
d
l


s ,ij k l mn
p ,ijklmn
B
ij k l mn
abcdef 
e
Bp 
Bp0   Bp1
1  2
i’
f
k’
p
n’
c
j’
l’
m’
d
e
ij k l mn
dkl
elm
fmn
abcdef   Fsianin Fsbijji Fscjk
Bps,,ijklmn
F
F
F
k j sl k  sml  snm
Very Complicated 12-qubit Interaction!
Quantum Circuit for Measuring Bp
2
1
8
7
6
3
9
p
12
10
11
5
4
1
2
3
4
5
6
7
8
9
10
11
12
b
b
b
b
b
b
b
b
b
c
e
a
d
c
e
a
d
c
e
a
d
c
e
a
d
0
c
e
a
b
a
b
a
b
X
c
e
a
c
e
a
d
c
e
a
d
c
e
a
d
c
e
a
d
1  Bp
N. Bonesteel, D.P. DiVincenzo, PRB 2012
Gate Count
2
1
8
7
6
3
9
p
12
10
11
4
5
1
2
3
4
5
6
7
8
9
10
11
12
b
c
e
a
d
b
c
e
a
d
b
b
c
e c
a e c
a e
d d a
0
8
2
10
43
24
5-qubit Toffoli Gates
4-qubit Toffoli Gates
3-qubit Toffoli Gates
CNOT Gates
Single Qubit Gates
b
371
392
b
c
a e
b a
a
b
b
b
b
c
c e
c e a
e a
a
d d d
b
c
e
a
d
X
1  Bp
CNOT Gates
Single Qubit Rotations
N. Bonesteel, D.P. DiVincenzo, PRB 2012
Outline
• Surface codes everywhere (and even color
codes)
• Various rough approximations of scalability
• Attempting to get error & leakage rates under
control – example from quantum dot qubits
• The highly complex classical world of surface
codes – example from UCSB/Google
• Outside the gate model – one-shot syndrome
measurement
• Inside the gate model – Fibonnaci anyons
What’s QEC for Solid State Physics?
“Surface code” is on the lips of many a solid-state device physicist these days.
I will document this phenomenon with some examples, from the
commonplace (CNOT to ancillas, then measure) to the more recondite (direct
parity measurement, intrinsic leakage of DFS qubits). I will give some
examples from current work in quantum-dot qubits. Mighty efforts are
underway to improve laboratory fidelities, which are however neither
quantitatively nor methodologically complete. Leakage reduction units are
starting to come over the horizon, but QEC could probably help more with
this. There are correspondingly mighty plans on the drawing board to collect
and process all the data that the surface code implies. I will show what small
parts of these plans have come to fruition; QEC should also do some work to
determine what is really the best thing to do with this avalanche of data,
when it comes. I will also touch on some examples where solid-state physics
definitely gives back to QEC, with Fibonacci quantum codes being one
example.
Project group A
Quantum information architectures
Error correction
A1-3
Interaction between qubits
• SAW spin transfer (A4)
• Semiconductor Josephson
elements (A5-7)
“Fibonacci” Levin-Wen Model
Levin & Wen, PRB 2005
v
Trivalent Lattice
H    Qv   Bp
v
Vertex
Operator
Qv = 0,1
p
“Fibonacci” Levin-Wen Model
Levin & Wen, PRB 2005
v
p
H    Qv   Bp
v
Vertex
Operator
Qv = 0,1
p
Plaquette
Operator
Bp = 0,1
Trivalent Lattice
arXiv:1205.1910
• No gate action among the three qubits
• Three qubits coupled dispersively to each of two nearly
degenerate resonant modes
• Measurement by reflectometry: tone in at + port, detect phase of
tone out at – port
• Designed as quantum eraser: measures only ZZZ (parity)
A two-resonator device for measuring the parity of three qubits:
χ=g2/Δ
s1, s2, s3 are the states of the three qubits (0,1)
χi is dispersive shift parameter
Dispersive coupling is the same for each qubit
and the same on both resonators (a and b)
Wave impedance
“looking into” port A
(transmission line theory)
(Z0=50Ω)
Reflection coefficient of full structure
NB
Alternative solution of Mabuchi and coworkers
Project group B
Semiconductor multi-qubit circuits
Transistors optimized
for cryogenic control
Control system
ZEA-2, FZJ
Engineering (B3)
Optical interface
to qubits: B7,B8
Qubits
Physics
Scalable multi-qubit circuits: B1
Material optimization: B2
Decoherence: B4-B6
High fidelity gates
• Well-established spin qubits,
key operations demonstrated
• Detailed knowledge of
dephasing characteristics
Key requirement:
Gates with error rate <~ 10-4
• What fidelities can be reached
in the face of realistic hardware
constraints?
• How can systematic errors be
eliminated?
Dephasing due to nuclear spins
New insights – Pronounced effects on Hahn echo from:
• Nuclear quadrupole splitting
T0
• g-factor anisotropy

DBz
J

90°
echo
amplitude
75°
60°
45°
30°
15°
0°
0
10
20
evolution time (µs)
30
S
Triple Quantum Dot Qubit
exchange-only qubit
PRB 87, 195309 (2013)
18.-21.08.2014 | DiVincenzo
Title
48
Triple Quantum Dot Qubit
exchange-only qubit
PRB 87, 195309 (2013)
18.-21.08.2014 | DiVincenzo
Title
49